JP2013076604A - Radiation detection instrument - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a portable radiation detection instrument which achieves improvement of S/N and spatial resolution.SOLUTION: The radiation detection instrument includes: a detection element group 21 having multiple detection elements 22 arranged on a support substrate 23; a shielding body 10 in which a pin hole 14 for letting radiation ray enter is formed on the front face and a slit 15 on the back face, which houses the detection element group 21; a signal processing substrate 31 provided outside of the shielding body 10 with a size larger than the width of the slit 15 for processing a detection signal detected by each detection element 22; and a relay substrate 32 passing through the slit 15 for connecting each detection element 22 and the signal processing substrate 31.

Description

  The present invention relates to a radiation detection apparatus that detects radiation such as gamma rays and X-rays.

  It is known that radiation such as γ-rays and X-rays (hereinafter simply referred to as γ-rays) has a great effect on the human body, but humans cannot see the radiation with their eyes. For example, it is important to reduce radiation exposure for workers working at nuclear power plants and residents near nuclear power plants.

  Conventionally, Patent Documents 1 and 2 disclose an apparatus for specifying the position of a radiation source that is portable and used at a work site or the like. Patent Document 1 discloses a γ-ray activity distribution imaging apparatus including a plurality of arranged γ-ray detectors and a collimator. Patent Document 2 discloses a portable gamma camera with a built-in power source for use during surgery.

Japanese Patent Laying-Open No. 2005-49136 Special table 2009-521694

  A radiation detection device that identifies the position of a radiation source is configured by a radiation detector arranged in a two-dimensional array or the like, and a collimator. The collimator is arranged in front of the radiation detector, thereby limiting the radiation direction of the radiation and allowing only radiation in a desired direction to enter the radiation detector.

  However, when the radiation detection apparatus is used in a place where there is a large amount of radiation, such as indoors in the nuclear power plant or outdoors near the power plant, the radiation enters the device from all directions. For this reason, in radiation detection, the background noise is large and the S / N (signal-to-noise ratio) is deteriorated.

  Since the generation and detection of γ-rays is a probabilistic phenomenon, the statistical error increases when the S / N is poor, leading to a reduction in spatial resolution with respect to specifying the position of the γ-ray source.

  On the other hand, in order to remove background noise around the device, it is conceivable to cover the device with a material having a high density such as lead or tungsten. However, when the entire apparatus is covered, the weight of the apparatus increases and the portability decreases.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a radiation detection apparatus that is portable and can realize improvement in S / N and spatial resolution.

  In order to solve the above-described problem, the radiation detection apparatus according to the present invention includes a detection element group having a plurality of detection elements arranged on a support substrate, and a pinhole for allowing radiation to enter the front surface. A slit is formed, and a radiation shield that houses the detection element group, and a detection signal detected by each detection element, is provided outside the radiation shield and has a dimension larger than the width of the slit. And a relay board that connects each of the detection elements and the signal processing board through the slit.

  The radiation detection apparatus according to the present invention has portability and can improve S / N and spatial resolution.

Sectional drawing of the radiation detection apparatus in 1st Embodiment. The external appearance perspective view which shows the shield of the radiation detection apparatus in 1st Embodiment from the front. The external appearance perspective view which shows the shield of the radiation detection apparatus in 1st Embodiment from the back. Explanatory drawing for comparing the shape of a pinhole. The front view of the shielding body at the time of screwing from the front. Sectional drawing of the radiation detection apparatus in 2nd Embodiment. FIG. 7 is an enlarged view of a part of an inner slit portion and an outer slit portion of the radiation detection apparatus of FIG. 6. Sectional drawing which shows especially the detection element group and pinhole part of a radiation detection apparatus in 3rd Embodiment. Sectional drawing which shows especially the other structural example of the element surrounding shielding member of the radiation detection apparatus in 3rd Embodiment. It is sectional drawing of the radiation detection apparatus in 4th Embodiment, and is a figure in case a pinhole part is arrange | positioned in the 1st position. It is sectional drawing of the radiation detection apparatus in 4th Embodiment, and is a figure in case a pinhole part is arrange | positioned in a 2nd position. The front view of the pinhole part of the radiation detection apparatus in 4th Embodiment. Sectional drawing of the radiation detection apparatus in 5th Embodiment. The graph which shows the relationship between the radiation detection position before the movement of a detection element group, and after a movement, and the gamma ray detection frequency. The figure which shows especially the detection element group of the radiation detection apparatus as a modification, a support substrate, and a pinhole part. Sectional drawing of the radiation detection apparatus which shows the other example of the attachment mechanism of a shield.

[First Embodiment]
A radiation detection apparatus according to a first embodiment of the present invention will be described with reference to the accompanying drawings.

  FIG. 1 is a cross-sectional view of the radiation detection apparatus 1 according to the first embodiment.

  FIG. 2 is an external perspective view showing the shield 10 of the radiation detection apparatus 1 in the first embodiment from the front.

  FIG. 3 is an external perspective view showing the shield 10 of the radiation detection apparatus 1 in the first embodiment from the back.

  In each embodiment, the radiation detected by the radiation detection apparatus 1 will be described as γ rays. Further, the radiation detection apparatus 1 defines the side on which the pinhole 14 is formed as the front side (front side) and the side on which the slit 15 is formed as the back side (rear side).

  The radiation detection apparatus 1 mainly includes a detection element group 21, a shield 10, a signal processing board 31, and a relay board 32.

  The detection element group 21 includes a plurality of detection elements 22 and is arranged in a matrix on a two-dimensional plane on the support substrate 23. For example, the detection elements 22 are arranged in a square. The detection element 22 is an element such as a semiconductor or a scintillator that generates electric charge or light in response to the incidence of γ rays.

  The shield 10 accommodates the detection element group 21 and has a pinhole collimator portion 11, a side shield portion 12, and a slit portion 13.

  The pinhole collimator portion (pinhole portion) 11 has a quadrangular frustum shape and forms the front surface of the shield 10 (front side from the detection element group 21). In the pinhole portion 11, a circular or rectangular pinhole 14 for allowing only the γ rays detected by the detection element 22 to pass is formed at a substantially central portion of the rectangular front surface 11 a (vertex portion). When the pinhole 14 is circular, it can be easily processed even when a hard material such as tungsten is used.

  When the pinhole 14 is rectangular, the area of the pinhole 14 can be reduced even when the measurement visual field is the same. As a result, the γ dose passing through the pinhole 14 can be reduced, and the background caused by γ rays incident from an unnecessary field of view can be reduced. In addition, when the pinhole 14 is rectangular, the measurement range for each detection element 22 is narrowed, so that the spatial resolution can be improved.

  Here, FIG. 4 is an explanatory diagram for comparing the shapes of the pinholes 14.

  Specifically, in order to target the detection element group 21 arranged in a square in the circular visual field 40, a visual field corresponding to a circumscribed circle of a square is necessary. On the other hand, the rectangular visual field 41 can cope with the outer shape of the detection element group 21 suitably.

  In addition, when the detection element group 21 is arranged in a circle, the same effect as when the outer shape of the detection element group 21 and the pinhole 14 are configured to be rectangular can be obtained by making the shape of the pinhole 14 circular. Can be obtained. That is, the shape of the pinhole 14 and the outer shape of the detection element group 21 may be similar.

  The side shielding part 12 has a rectangular shape with both ends open. The side shield 12 surrounds the surrounding side surface other than the detection surface and the back surface of the detection element group 21. The side shielding part 12 fixes the detection element group 21 by, for example, holding the support substrate 23 of the detection element group 21 in the notch 12a. The side shielding part 12 preferably has a small inner dimension within a range where it does not contact the detection element group 21.

  The slit portion 13 is a plate-like member in which a plurality of slits 15 are formed, and forms the back surface of the shield 10. For example, the slit portion 13 is divided into two in a direction orthogonal to the direction of the slit 15. It is preferable to make the width of the slit 15 as small as possible so that the relay substrate 32 described later can pass through.

  As shown in FIG. 3, the shield 10 is fixed by the attachment mechanism 17 so that the pinhole portion 11, the side shield portion 12, and the slit portion 13 are integrated. For the attachment mechanism 17, for example, screwing means made of aluminum or stainless steel screws or taps can be applied. The shield 10 is screwed from the front to the back or from the back to the front.

  Here, FIG. 5 is a front view of the shield 10 when screwed from the front. In order to perform accurate measurement with the detection elements 22, it is necessary to remove the pinhole portion 11 from the shield 10 and perform calibration by irradiating each detection element 22 with a known uniform dose of γ rays before measurement. . In this case, as shown in FIG. 5, the shield 10 is screwed from the front surface, so that only the pinhole portion 11 can be easily removed from the shield 10 and the calibration of the detection element 22 is facilitated. be able to.

  The attachment mechanism 17 is preferably provided at a position where the shielding effect of the shield 10 is maintained by a screw or a tap. For example, the passing distance of the γ-ray A shown in FIG. 5 that enters the four corners of the shield 10 from an oblique direction is about 10 mm × √2 = 14 mm when the thickness of the shield 10 is 10 mm. For this reason, if the screw used for the attachment mechanism 17 is about M4, a sufficient shielding effect can be maintained.

  In order to avoid a change in the shielding effect due to screwing, the same material as that of the shielding body 10 may be used for the screw, or a shielding body may be added due to the difference in shielding effect.

  The thickness of each part of the shield 10 is set according to the energy of the radiation to be detected. The shield 10 is made of a material having a high density such as lead, tungsten, or gold. For example, when the detection target is γ-ray 660 keV derived from Cs-137, the thickness of the shield 10 is preferably about 10 mm when formed of tungsten and about 20 mm when formed of lead.

  As shown in FIG. 1, the signal processing board 31 is connected to the detection element 22 via the relay board 32 to adjust the power supply voltage and process the detection signal output from the detection element 22. The signal processing board 31 has a size larger than the size (width) of the slit 15 of the slit portion 13.

  The relay substrate 32 passes through the slit 15 and connects the detection element 22 (support substrate 23) and the signal processing substrate 31 via a connector. The relay board 32 is, for example, a flexible printed board, and has a thickness smaller than the width of the slit 15. The material of the relay board 32 can be arbitrarily selected.

  Next, the operation of the radiation detection apparatus 1 in the first embodiment will be described.

  At the time of γ-ray detection, the radiation detection apparatus 1 is installed at a detection target location. For example, γ-rays from Hotspot, where many γ-ray sources exist, pass through the pinhole 14 of the shield 10 and enter the plurality of detection elements 22.

  Each detection element 22 on which the γ rays are incident generates charge or light corresponding to the energy of the γ rays. The detection element 22 converts the generated charge or light into a voltage signal and outputs the voltage signal to the signal processing board 31 via the relay board 32. The signal processing board 31 counts the number of γ rays detected by performing predetermined signal processing. Note that a required computer or display device may be arranged at the subsequent stage of the signal processing board 31.

  Here, not only the γ-rays irradiated from the front surface and passing through the pinhole 14 but also γ-rays may be incident on the detection element group 21 from the side surface and the back surface. The γ rays incident from the side and back become noise in the detection signal, which hinders accurate detection.

  On the other hand, the radiation detection apparatus 1 in the first embodiment covers not only the front surface of the detection element group 21 but also the side surface and the back surface thereof with the shield 10. The γ-rays that can be irradiated from all directions are shielded by the shield 10 or pass through the shield 10, so that the intensity decreases, and noise of the signal measured by the detection element 22 can be reduced.

  In addition, when γ rays pass through the slit 15 of the slit portion 13 that forms the back surface of the shield 10 and enter the detection element 22, a bright line corresponding to the width of the slit 15 is observed. On the other hand, since the radiation detection apparatus 1 in the first embodiment arranges the signal processing substrate 31 larger than the width of the slit 15 on the back surface of the slit portion 13, it can shield γ rays that can enter from the back surface. That is, γ-rays can be suitably shielded without providing a new configuration for shielding γ-rays that can enter from the back surface.

  In general, the shielding ability of gamma rays depends on the density of the substance. For this reason, when the slit portion 13 is formed of tungsten having a thickness of about 10 mm (density 5.4 g / cm 3), the signal processing substrate 31 is formed by a glass epoxy substrate (1.85 g / cm 3) having a length of about 30 mm. By forming in {circle around (3)}, a shielding ability equivalent to that of the slit portion 13 is obtained, and no bright line corresponding to the γ rays incident from the slit 15 is observed.

  In the first embodiment as described above, the radiation detection apparatus 1 that is lightweight and portable without requiring a member for shielding more than necessary by shielding the periphery of the detection element group 21 with the shield 10. Can be realized.

  Since the radiation detection apparatus 1 has a sufficient radiation shielding ability while being reduced in weight, the radiation detection apparatus 1 can accurately measure even in an environment with many backgrounds when specifying the position of the radiation source.

  Further, the radiation detection apparatus 1 can improve the spatial resolution by setting the shape of the pinhole 14 corresponding to the arrangement of the detection element groups 21.

[Second Embodiment]
A radiation detection apparatus according to a second embodiment of the invention will be described with reference to the accompanying drawings.

  FIG. 6 is a cross-sectional view of the radiation detection apparatus 51 in the second embodiment.

  FIG. 7 is an enlarged view of a part of the inner slit portion 63a and the outer slit portion 63b of the radiation detection apparatus 51 of FIG.

  The radiation detection apparatus 51 in the second embodiment is different from the first embodiment in that a plurality of slit portions 63a and 63b of the shield 60 are provided. In the description of the second embodiment, configurations and parts corresponding to those of the first embodiment are denoted by the same reference numerals, and redundant description is omitted.

  The radiation detection device 51 mainly includes a detection element group 21, a shield 60, a signal processing board 31, and a relay board 32.

  The shield 60 has a pinhole part 61, a side shield part 62, an inner slit part 63a, and an outer slit part 63b. The pinhole part 61 is flat plate shape, and the pinhole 14 is formed in the substantially center part.

  The inner slit portion 63a is disposed on the back surface of the shield 60 and immediately after the side shield portion 62 (on the back surface side). The outer slit portion 63b is disposed on the back surface of the shield 60 and immediately after the inner slit portion 63a (on the back surface side). The inner slit portion 63a and the outer slit portion 63b are fixed in close contact with the relay substrate 32 sandwiched therebetween.

  A plurality of inner slits 66a and outer slits 66b are formed in the inner slit part 63a and the outer slit part 63b, respectively. The inner slit 66a and the outer slit 66b are formed so that the relay substrate 32 has a crank shape in the thickness direction of the slit portions 63a and 63b, and the slits 66a and 66b are not overlapped. The thicknesses of the inner slit 66a and the outer slit 66b may be different.

  As shown in FIG. 7, the inner slit portion 63 a has a convex portion 68 a that projects in the forward direction of the shield 60. The convex portion 68a is provided at a position corresponding to the position where the outer slit 66b of the outer slit portion 63b is formed. The convex portion 68a of the inner slit portion 63a preferably has a length corresponding to the thickness of the outer slit portion 63b. The outer slit portion 63 b has a convex portion 68 b that protrudes in the rearward direction of the shield 60. The convex portion 68b is provided at a position corresponding to the position where the inner slit 66a of the inner slit portion 63a is formed. The convex portion 68b of the outer slit portion 63b preferably has a length corresponding to the thickness of the inner slit portion 63a.

  Next, the operation of the radiation detection apparatus 51 in the second embodiment will be described.

  In the radiation detection apparatus 1 according to the first embodiment, the signal processing substrate 31 having a width larger than the width of the slit 15 is provided on the back side of the slit portion 13, thereby suppressing the incidence of γ rays on the detection element 22. However, in an environment where radiation can enter from all directions, γ rays may enter the detection element 22 through a gap between the slit 15 and the signal processing board 31 or the relay board 32.

  Therefore, the radiation detection device 51 according to the second embodiment further enhances the shielding effect by providing the inner slit portion 63a and the outer slit portion 63b against γ rays that can enter the detection element 22 from the back side. Can do.

  Specifically, the inner slit 66a and the outer slit 66b are arranged in steps so as not to overlap each other in the thickness direction of the slit portions 63a and 63b. Thereby, even if γ rays pass through the outer slit 66b of the outer slit portion 63b, the inner slit portion 63a is further provided on the front side. Can be blocked.

  The inner slit portion 63a and the outer slit portion 63b are provided with convex portions 68a and 68b, respectively. Thereby, even if the inner slit 66a and the outer slit 66b are provided where the thickness of the inner slit portion 63a and the outer slit portion 63b is reduced, the thickness reduced by the respective slits 66a and 66b is reduced to the convex portion 68a, It can be compensated by 68b. Accordingly, the γ dose transmitted through the slit portions 63a and 63b is uniform over the entire area of the inner slit portion 63a and the outer slit portion 63b. Moreover, it can have the thickness for two slit parts over the whole area | region of the inner slit part 63a and the outer slit part 63b, and can improve the shielding effect of the shielding body 60. FIG.

  The radiation detection apparatus 51 in the second embodiment can block γ rays that can enter the detection element 22 from the inner slit 66a and the outer slit 66b regardless of the length and type of the signal processing board 31 and the relay board 32. For this reason, the radiation detection apparatus 51 can reduce the influence of a background and can improve S / N.

[Third Embodiment]
A third embodiment of the radiation detection apparatus according to the present invention will be described with reference to the accompanying drawings.

  FIG. 8 is a cross-sectional view specifically showing the detection element group 21 and the pinhole portion 11 of the radiation detection apparatus 71 in the third embodiment.

  The radiation detection apparatus 71 in the third embodiment is different from the first and second embodiments in that an element surrounding shielding member 93 is provided in the detection element group 21. In the description of the third embodiment, configurations and parts corresponding to those in the first and second embodiments are denoted by the same reference numerals, and redundant description is omitted.

  The radiation detection device 71 mainly includes a detection element group 21, a shield 10, a signal processing board 31, and a relay board 32 (see FIG. 1).

  The element surrounding shielding member (shielding member) 93 is disposed so as to surround each detection element 22 and is made of a material having a high density such as tungsten. The shielding member 93 can set an inclination with respect to the support substrate 23 according to the direction of the γ-ray A incident on each detection element 22.

  Next, the operation of the radiation detection apparatus 1 in the third embodiment will be described.

  When γ rays enter the detection element 22, absorption or scattering of γ rays occurs in the substance. When γ-rays are absorbed, the radiation detection apparatus 71 can specify the γ-ray source position. On the other hand, when γ-rays are scattered, the radiation detection apparatus 71 cannot identify the scattered γ-ray source position, and the position resolution decreases.

  Therefore, when the shielding member 93 is provided between the detection elements 22, scattered γ rays scattered by a certain detection element 22 are shielded by the shielding member 93, and the influence of the scattered γ rays between the detection elements 22 can be reduced. γ rays are more easily absorbed by substances as the energy decreases. For this reason, by arranging the shielding member 93 between the detection elements 22, it is possible to sufficiently shield the scattered γ rays between the detection elements 22.

  In addition, by providing the shielding member 93, the radiation detection apparatus 71 can reduce the influence of scattered γ rays, so that the spatial resolution can be improved.

  The shielding member 93 may be elongated in the direction of the pinhole 14 (forward direction) as shown in FIG.

  FIG. 9 is a cross-sectional view specifically showing another configuration example of the element surrounding shielding member 93 of the radiation detection apparatus 71 in the third embodiment.

  The element surrounding shielding member (shielding member) 95 extends from the detection element 22 in the direction of the pinhole 14 as compared with the shielding member 93 shown in FIG. It is desirable that the shielding member 95 is long as long as it does not interfere with the adjacent shielding member 95.

  The γ rays pass through the shield 10 not a little. However, the radiation detection apparatus 71 can suitably shield γ rays from directions other than the direction of the pinhole 14 by extending the shielding member 95 as close as possible to the pinhole 14.

  Further, the radiation detection apparatus 71 can further improve the spatial resolution by reliably shielding the γ-ray transmitted through the shield 10 or the γ-ray scattered by the detection element 22 with the shielding member 95.

[Fourth Embodiment]
A fourth embodiment of the radiation detection apparatus according to the present invention will be described with reference to the accompanying drawings.

  FIG. 10 is a cross-sectional view of the radiation detection apparatus 101 according to the fourth embodiment, and shows a case where the pinhole portion 111 is disposed at the first position.

  FIG. 11 is a cross-sectional view of the radiation detection apparatus 101 according to the fourth embodiment, and shows a case where the pinhole portion 111 is disposed at the second position.

  FIG. 12 is a front view of the pinhole portion 111 of the radiation detection apparatus 101 according to the fourth embodiment.

  The radiation detection apparatus 101 according to the fourth embodiment is different from the first to third embodiments in that the pinhole portion 111 of the shield 110 moves in the front-rear direction. In the description of the fourth embodiment, configurations and portions corresponding to those in the first to third embodiments are denoted by the same reference numerals, and redundant description is omitted.

  The radiation detection apparatus 101 mainly includes a detection element group 21, a shield 110, a signal processing board 31 (see FIG. 1), and a relay board 32.

  The shield 110 has a pinhole drive unit 120, a pinhole unit 111, a side shield unit 112, and a slit unit 13.

  The pinhole driving unit 120 includes a stepping motor connected to the pinhole unit 111 and a control device that controls the motor. The pinhole drive unit 120 moves the pinhole unit 111 to a predetermined position by automatic or manual control. As shown in FIGS. 10 and 11, the pinhole driving unit 120 drives the pinhole unit 111 in the front-rear direction (front-rear direction with respect to the radiation incident direction). The pinhole drive unit 120 drives the pinhole unit 111 in a range that does not contact the detection element group 21.

  As shown in FIG. 12, the pinhole portion 111 has a drive port 111a and a stopper 111b. The drive ports 111a are formed on a pair of opposing sides of the pinhole portion 111, and are formed to slide the pinhole portion 111 in the front-rear direction with respect to the pair of opposing side walls 112a of the side shield portion 112. The The stopper 111b restricts the pinhole portion 111 from moving outside the predetermined range with respect to the side shield portion 112.

  Next, the operation of the radiation detection apparatus 101 in the fourth embodiment will be described.

  As shown in FIG. 10, when the position of the pinhole part 111 in the front-rear direction is brought close to the detection element group 21 by the pinhole driving unit 120, the radiation measurement field of view for the detection element group 21 is widened. On the other hand, as shown in FIG. 11, when the position of the pinhole portion 111 is moved away from the detection element group 21, the radiation measurement field of view becomes narrow.

  When the radiation measurement field is widened, the position resolution of the radiation detection apparatus 101 deteriorates, but the number of incident γ rays increases. When the radiation measurement field of view is narrowed, the position resolution of the radiation detection apparatus 101 is improved, but the number of incident γ rays is reduced. The radiation detection apparatus 101 can arbitrarily change the spatial resolution and S / N by changing the position of the pinhole unit 111 using the pinhole driving unit 120.

  The radiation detection apparatus 101 according to the fourth embodiment increases the number of incident γ rays over the position resolution when the radiation intensity to be measured is weak, and improves the position resolution by reducing the number of incident γ rays when the radiation intensity is high. be able to. Therefore, the radiation detection apparatus 101 can change the improvement of the spatial resolution and S / N with any setting of the user.

[Fifth Embodiment]
A fifth embodiment of the radiation detection apparatus according to the present invention will be described with reference to the accompanying drawings.

  FIG. 13 is a cross-sectional view of the radiation detection apparatus 131 according to the fifth embodiment.

  The radiation detection apparatus 131 according to the fifth embodiment is different from the first to fourth embodiments in that it includes an element driving unit 140 that moves the detection element group 21 in a two-dimensional direction. In the description of the fifth embodiment, configurations and parts corresponding to those in the first to fourth embodiments are denoted by the same reference numerals, and redundant description is omitted.

  The radiation detection device 131 mainly includes a detection element group 21, a shield 10, a signal processing board 31 (see FIG. 1), a relay board 32, and an element driving unit 140.

  The element driving unit 140 includes one stepping motor that drives in the x-axis and y-axis directions, and a control device that controls the motor from the outside. The element driving unit 140 is connected to the support substrate 23 that holds the detection element group 21. The element driving unit 140 sets a distance smaller than the dimension in the xy direction of each detection element 22 in the xy direction in the xy plane orthogonal to the z direction (incident direction of γ rays) that is the front-rear direction of the radiation detection device 131. To drive.

  The element driving unit 140 is fixed to the connection board 141, and the connection board 141 is fixed to the side shield part 12 of the shield 10. The connection substrate 141 is connected to the support substrate 23 by a flexible lead wire 142 or the like. The connection board 141 is connected to the relay board 32 with a connector, and outputs a detection signal output from the detection element 22 to the relay board 32.

  Next, the operation of the radiation detection apparatus 131 in the fifth embodiment will be described.

  The element driving unit 140 moves the detection element group 21 by a range shorter than the dimension of the detection element 22 in the xy direction. Each detection element 22 detects γ-rays at a position shifted within the moved range.

  FIG. 14 is a graph showing the relationship between the radiation detection position and the number of times of γ-ray detection before and after the detection element group 21 is moved.

  The radiation detection device 131 has a sufficient position resolution when the radiation detection device 131 is fixed at a fixed point and continuously photographed, for example, when the number of detection elements 22 is small or when the interval between adjacent detection elements 22 is large. It may not be possible. On the other hand, by moving the detection element group 21 in the xy direction by the element driving unit 140, the intensity distribution of data normally acquired by the detection element 22 can be complemented. As a result, the radiation detection apparatus 131 can improve the position resolution.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  For example, the shape of the pinhole portion 11 may be a quadrangular frustum shape, a plate shape, a trapezoidal shape, or a triangular shape, and can be arbitrarily selected. Moreover, the shape of the pinhole 14 may be either circular or rectangular.

  The detection element group 21 may be disposed on a spherical support substrate. FIG. 15 is a diagram specifically showing a detection element group 21, a support substrate 150, and a pinhole portion 11 of a radiation detection apparatus as a modification.

  The support substrate 23 is installed such that the center of the spherical surface is substantially at the center of the pinhole 14 and the light receiving surface of the detection element 22 faces substantially the center of the pinhole 14. Thereby, compared with the case where the detection element group 21 is arranged on a surface perpendicular to the incident direction of γ-rays, the incident γ-rays have a longer distance to pass through the detection elements 22 and can be absorbed equally efficiently.

  The attachment mechanism 17 of the shield 10 may be configured as shown in FIG. 16 in addition to screwing. FIG. 16 is a cross-sectional view of the radiation detection device 161 showing another example of the attachment mechanism of the shield 10.

  The side shield part 12 and the slit part 13 are fixed by a support member 170. On the other hand, the pinhole portion 11 is fixed by a plate 171 provided on the front surface of the support member 170 and provided with a jig. As for the support member 170, only the pinhole part 11 becomes removable from the shield 10 as needed. Thereby, the removal of the pinhole part 11 at the time of calibration of the detection element 22 etc. can be made easy.

  Two or more slit portions 13 may be provided as long as the weight reduction of the radiation detection apparatus is not hindered.

1, 51, 71, 101, 131, 161 Radiation detection device 10, 60, 110 Shield 11, 61, 111 Pinhole collimator (pinhole)
12, 112 Side shield part 13 Slit part 14 Pinhole 15 Slit 17 Mounting mechanism 21 Detection element group 22 Detection element 23, 150 Support board 31 Signal processing board 32 Relay board 63a Inner slit part 63b Outer slit part 66a Inner slit 66b Outer slit 68a, 68b Protrusions 93, 95 Element surrounding shielding member (shielding member)
111a Drive port 111b Stopper 112a Side wall 120 Pinhole drive unit 140 Element drive unit 141 Connection board

Claims (9)

A detection element group having a plurality of detection elements arranged on a support substrate;
A pinhole for allowing radiation to enter is formed on the front surface, a slit is formed on the back surface, and a radiation shield that houses the detection element group,
Processing a detection signal detected by each of the detection elements, a signal processing board provided outside the radiation shield and having a dimension larger than the width of the slit;
A radiation detection apparatus comprising: a relay substrate that connects each detection element and the signal processing substrate through the slit. The radiation shield forms a back surface of the radiation shield, and has an inner slit portion and an outer slit portion each formed with a slit,
The radiation detection apparatus according to claim 1, wherein the inner slit portion and the outer slit portion are arranged such that the slits do not overlap each other. The inner slit portion has a convex portion protruding in the front direction of the radiation shield at a position corresponding to the position where the slit of the outer slit portion is formed,
The radiation detection apparatus according to claim 2, wherein the outer slit portion has a convex portion protruding in a back direction of the radiation shield at a position corresponding to a position where the slit of the inner slit portion is formed.   The radiation detection apparatus according to any one of claims 1 to 3, further comprising a radiation shielding member disposed between the adjacent detection elements. The radiation shield has a pinhole portion in which the pinhole is formed, which is the front surface of the radiation shield.
The radiation detection apparatus according to claim 1, further comprising a pinhole driving unit that drives the pinhole unit back and forth with respect to an incident direction of the radiation.   The radiation detection apparatus according to claim 1, further comprising an element driving unit configured to drive the detection element group in a plane orthogonal to the incident direction of the radiation.   The radiation detection apparatus according to claim 1, wherein an outer shape of the detection element group and a shape of the pinhole are similar.   The radiation detection apparatus according to claim 1, wherein the support substrate has a spherical shape with the pinhole center as a substantially spherical center. The radiation shield has a pinhole portion in which the pinhole is formed, which is the front surface of the radiation shield.
The radiation detection apparatus according to any one of claims 1 to 8, further comprising an attachment mechanism capable of detaching the pinhole portion from the radiation shield.

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